Converter device and system including converter device

ABSTRACT

Systems and apparatus may include converter device(s), a matrix switch, processor(s), and memory(s), where one or more of the converter devices provide video input signals to the matrix switch. A processor may determine if one of a plurality of video signals input to the matrix switch includes data representative of identification information overlain on a video image derived from one of the plurality of video signals. The determination may be based on a flag value stored in the converter device(s). The flag value may be retrieved by a server coupled to the matrix switch. If the information is included in the video signal, the video signal may be passed through a path in a matrix switch configured by the processor. If the information is not included in the video signal, the data representative of identification information may be retrieved from the converter device and then overlain on the video image.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application for patent is a continuation application of U.S.patent application Ser. No. 14/637,332 entitled “Converter Device andSystem Including Converter Device” filed Mar. 3, 2015, which in turnclaims priority to U.S. provisional application No. 61/947,934 entitled“Smart Converter Apparatus and Communication System” filed Mar. 4, 2014,the entire disclosures of which are hereby expressly incorporated byreference.

BACKGROUND

Field

Various features relate to interface devices for video and audio, and inparticular, to interface devices adapted to receive data in any one of aplurality of format types, convert the data to one predetermined formattype, add metadata, and output the converted data including the metadatafor analysis and/or storage.

Background

Today's surgical operating rooms contain a myriad of technology. Thetechnology includes equipment that provides video as an output. As usedherein, the term video is meant to encompass, for example, moving imagesof live action (e.g., images of an interior of a patient's body as alaparoscope is maneuvered therein, of an interior of a large intestineas an endoscope is advanced through the intestine, or of an operatingroom as operating room staff move about therein), still images (e.g.,individual frames captured from a moving image of live action),real-time or near real time images that have been generated with the aidof a computing device (e.g., images of an interior of a patient's bodygenerated by a sonogram machine, a magnetic resonance imaging (MRI)machine, or an X-ray machine), as well as graphic representations ofstatic, semi-static, and dynamic measurements of parameters (e.g., animage from a screen of an electrocardiograph machine, a display of boldoxygen concentration, or blood pressure). The preceding list isdemonstrative and is not intended to be limiting. Reference to video isalso intended to encompass the signals presented to video monitors(e.g., monitors, televisions, cathode ray tubes (CRTs), liquid crystaldisplays (LCDs)) that drive the circuitry of video monitors to generateimagery. Some pieces of equipment may add some aspect of patientidentification to their images and this information may typically beprovided outside of the boundary edges of the images.

The video may be provided to video monitors integrated with theequipment (e.g., a video monitor integrated with a sonogram machine)and/or to video monitors within the operating room, and/or to videomonitors outside of the operating room. The video may also be recordedat the time of its production, either by a recording device integratedwith the equipment or by an external recording device coupled to theequipment.

Video may be obtained, for example, from video pickup devices (andcircuitry associated therewith) or video output ports of medical devicessuch as endoscopes, laparoscopes, orthoscopes, microscopes, roboticsurgical systems, surgical-light mounted video cameras, and videocameras mounted in the operating room that provide images of theoperating room itself. Additional video may be obtained, for example, inthe form of graphic displays of vital signs, such as those associatedwith electrocardiograph devices, bold oxygen monitoring device, andblood pressure monitoring device. Still further, video imagery may beobtained from fluoroscopes, X-ray machines (commonly referred to as “CRmachines”), magnetic resonance image (MRI) machines, computed axialtomography (CAT) scanners, and/or other types of imaging devices. Thepreceding lists are demonstrative and are not intended to be limiting.

Instruments, machines, and/or devices found in today's operating roomsare made by many manufacturers. Each manufacturer may have a differentpreference for how its video signals are presented to video monitors(e.g., component video, red-green-blue (RGB) video, separate or supervideo (S-Video), digital signals) and what formats are used (e.g.,analog NTSC or PAL or digital High Definition Multimedia Interface(HDMI), among others). Additionally, video signals may be provided fromthe equipment to the video monitors wirelessly, via copper wire, or viafiber optic cable. As used herein, a video output of any given piece ofequipment may be referred to as a video feed.

There presently exists system that provides digital, video routing anddisplay solutions to such environments as, for example, operating rooms,hybrid rooms, catheterization suites, interventional suites, andelectrophysiology (EP) labs. The system may be configured withvideoconferencing and streaming, multiview windowing, image capturing,video recording, and/or hands-free voice over Internet Protocol (IP)communication. The system may provide a user with comprehensive controlover the system and its functionality, including, for example, touchrouting of images from video and data sources to video monitor monitors.

The system may be useful, for example, for display of the video imageryof one or more pieces of equipment on one or more video monitors thatare not integral to the equipment itself. Such video monitors may beconveniently positioned for a surgeon's use during surgery. The systemmay also be useful, for example, for remote (i.e., in a location otherthan the operating room) observation, training, and conferencing. Thecomponents of the system may be dispersed to multiple locations; somecomponents may be in the operating room while other components may beoutside of the operating room. The components of the system may becoupled to one another via wire, fiber optic cable, and/or via radiowaves (i.e., wireless).

While the system is useful, several problems exist. For example, it ispossible that the video from a given piece of equipment may not bedisplayed on a video monitor, despite the system having been programmedto route the video from the given piece of equipment to the videomonitor. It may not be possible for operating room staff (or hospitalstaff in general) to determine if the lack of a video image is due to afailure of the given piece of equipment, a failure of the system or oneof its components, or a failure of any of the wired, wireless, and/orfiber optic interconnections between the given piece of equipment, aserver of the system, and the video monitor. Trouble-shooting such aproblem can be time consuming and is, in general, not something thatoperating room staff (or hospital staff in general) are trained orequipped for.

Additionally, while the system may help in locating various pieces ofequipment within the hospital setting, it is not able to provideinformation about the equipment with a degree of granularity that wouldbe helpful, for example, in distinguishing between features of twopieces of equipment that share a same general name, such as“microscope.”

Additionally, the system cannot apply such granular information (i.e.,equipment information), and/or patient information, to video imagespresented on video monitors. Nor is the system able to remove patientinformation (or not display patient information if it is already presentin a video stream) from a video monitor in a public area, such as at aconference, so as to comply with the Health Insurance Portability &Accountability Act of 1996 (HIPPA) regulations.

What is needed is a system, device, and/or method that solves one ormore of these and/or other problems which may be recognized in theexisting system.

SUMMARY

A system including one or more computers can be configured to performparticular operations or actions by virtue of having software, firmware,hardware, or a combination of them installed on the system so that inoperation they cause the system to perform the actions. One or morecomputer programs can be configured to perform particular operations oractions by virtue of including instructions that, when executed by dataprocessing apparatus, cause apparatus of the system to perform theactions.

In one general aspect, an apparatus may include a video converter, aprocessing circuit communicatively coupled to the video converter, and anon-volatile memory circuit communicatively coupled to the processingcircuit, the non-volatile memory circuit may be configured to store dataassociated with a medical device that is associated with the apparatus.The data may include elapsed operating time of the medical device, amaintenance due date of the medical device, a flag indicative of apresence of patient information in an output of the medical device, aflag indicative of a presence of modality information in an output ofthe medical device, input video status, asset tracker identificationnumber or sequence of numbers and or letters, and/or one or more x-ycoordinates for the location of patient information on a video image.

According to one aspect of the apparatus, the processing circuit may beconfigured to dynamically select an output signal of the apparatus. Theoutput signal may be selected, for instance, from between datarepresentative of a video signal received at an input of the apparatusand data representative of a pre-defined video pattern. According to oneaspect, the selection of the output signal may be based on adetermination of validity of the video signal at the input of theapparatus. An image generator may be further coupled to the processingcircuit. According to one aspect, a switch may be coupled to the videoconverter and the image generator, where the processing circuit may beconfigured to switch an output of the switch between the video converterand the image generator. According to this aspect, the processingcircuit automatically switches the output of the switch between thevideo converter and the image generator based on a determination of thevalidity of the video signal that is input to the apparatus.

Another general aspect may include a method of converting video data,operational at a converter device. The method may include transmitting avalue indicative of whether predetermined information will be includedin video data to be received from equipment coupled to the converterdevice and determining if the converter device is receiving valid videodata from the equipment coupled to the converter device. If theconverter device is receiving valid video data, the converter device mayconvert the received video data from a first format to a secondpredefined format and may transmit the converted video data in thesecond format to a digital video matrix. If the converter device is notreceiving valid video data, the converter device may generate datarepresentative of a predetermined image and may transmit the generateddata to the digital video matrix.

Still another aspect includes a system. The system may include a matrixswitch configured to receive a plurality of video signals from videosources, a processor communicatively coupled to the matrix switch, afirst memory communicatively coupled to the processor, where theprocessor may be configured to execute instructions stored in the firstmemory, the instructions causing the processor to determine if one ofthe plurality of video signals includes data representative ofidentification information overlain on a video image derived from one ofthe plurality of video signals. The instructions may further cause theprocessor to pass the video signal through a path in a matrix switchconfigured by the processor and add data representative ofidentification information overlain on the video image derived from theone of the plurality of video signals if the one of the video signaldoes not include the data or pass the video signal through the path inthe matrix switch configured by the processor if the video signal doesinclude the data.

Another aspect includes still another system. The system may include avideo converter, a video converter processor communicatively coupled tothe video converter, a first memory communicatively coupled to the videoconverter processor, a system processor, and a second memorycommunicatively coupled to the system processor. The system may furtherinclude a matrix switch communicatively coupled to the system processorand the video converter, where an output of the video converter iscommunicatively coupled to one of a plurality of matrix switch inputs.Furthermore, the system processor may configure the matrix switch tocommunicatively couple the one of the plurality of matrix switch inputsto one of a plurality of matrix switch outputs. Additionally, the systemprocessor may execute instructions stored in the second memory to causethe system processor to determine if the video converter iscommunicatively coupled to a video source that includes identificationinformation overlain on a video image derived from a video signalreceived from the video source. If not, the processor may pass the videosignal from the one of the plurality of matrix switch inputs to the oneof the plurality of matrix switch outputs and add identificationinformation to the video signal to appear as an overlay on the videoimage derived from the video signal. If so, the processor may pass thevideo signal from the one of the plurality of matrix switch inputs tothe one of a plurality of matrix switch outputs.

Yet another aspect may provide a converter device including a processorand a memory, where the memory may store instructions that, whenexecuted by the processor, cause the processor to transmit a valueindicative of whether predetermined information will be included invideo data to be received from equipment coupled to the converter deviceand determine if the converter device is receiving valid video data fromthe equipment coupled to the converter device. According to this aspect,if the converter device is receiving valid video data then the processormay execute instructions to convert the received video data from a firstformat to a second predefined format, and may then transmit theconverted video data in the second format to a digital video matrix.Still according to this aspect, if the converter device is not receivingvalid video data then the processor may execute instructions to generatedata representative of a predetermined image and transmit the generateddata to the digital video matrix.

Still yet another aspect may provide for a system that includes aserver. According to this aspect, the server may include a serverprocessor, a server memory, communicatively coupled to the serverprocessor, a matrix switch communicatively coupled to the serverprocessor, a first plurality of matrix switch input portscommunicatively coupled to the matrix switch, a second plurality ofmatrix switch output ports communicatively coupled to the matrix switch,the matrix switch input ports multiplexed to the matrix switch outputports under control of the server processor. According to this aspect,the system may also include a converter apparatus. The converterapparatus may have an input configured to receive a video signal from avideo source and an output communicatively coupled to one of the firstplurality of matrix switch input ports. The converter apparatus mayfurther include a video converter configured to convert the video signalreceived from the video source from a first format into a second format,and transmit the converted video signal to the one of the firstplurality of matrix switch input ports, a processing circuitcommunicatively coupled to the video converter, a non-volatile memorycircuit communicatively coupled to the processing circuit, thenon-volatile memory circuit configured to store data associated with thevideo source, the data may include at least one flag indicative of apresence of identification information in the video signal from thevideo source. According to this aspect, the server processor may executecommands stored in the server memory to retrieve a value of the at leastone flag stored in the non-volatile memory of the converter apparatus,pass the video signal from the one of the first plurality of matrixswitch input ports to one of the second plurality of matrix switchoutputs and add identification information to the video signal to appearas an overlay on a video image derived from the video signal if thevalue of the at least one flag indicates identification information isnot present. Alternatively, the server processor may execute commandsstored in the server memory to pass the video signal from the one of thefirst plurality of matrix switch inputs to the one of the secondplurality of matrix switch outputs if the at least one flag indicatesidentification information is present. The system according to thisaspect may further include a first communication interfacecommunicatively coupled to the server processor, and a secondcommunication interface communicatively coupled to the processingcircuit and the first communication interface. According to this aspectthe server processor may retrieve the value of the at least one flagstored in the non-volatile memory of the converter apparatus viamessaging between the first communication interface and the secondcommunication interface. According to one feature, the server memory maybe located remote to the non-volatile memory circuit. According toanother feature, the video converter, processing circuit, andnon-volatile memory may be logically and/or physically coupled to thevideo source.

The above described aspects and features may include computer systems,apparatus, and computer programs recorded on one or more computerstorage devices, each configured to perform the actions of any of themethods described above.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 provides an example of an operational environment 100 in which asystem, including a converter device, may find utility.

FIG. 2 is a block diagram illustrating an aspect in which three rooms,each served by their own server, send video out over a network.

FIG. 3 is a block diagram of a converter device according to one aspect.

FIG. 4 illustrates an informational message, such as one that may begenerated by an image generator of a converter device.

FIG. 5 is an illustration of a video monitor showing equipmentinformation (e.g., modality) and patient information in the image fielddisplayed by the video monitor.

FIGS. 6A and 6B illustrate de-identification, where areas holdinginformation may be masked.

FIG. 7 is a block diagram illustrating a method of set-up and use of aconverter device.

FIG. 8 is a block diagram illustrating a method 800 of use of aconverter device.

DETAILED DESCRIPTION

In the following description numerous specific details may be set forthin order to provide a thorough understanding of the invention. However,one skilled in the art would recognize that the invention might bepracticed without these specific details. In other instances, well knownmethods, procedures, and/or components have not been described in detailso as not to unnecessarily obscure aspects of the invention.

Overview

Described herein are one or more components of a system, including amatrix switch, that provides for the routing of multiple input videosignals to one or more of a plurality of output video signals. Theformat of the video signals may be a high speed digital video interfacesuch as Digital Video Interface (DVI) or some other digital videointerface. DVI is a video monitor interface developed by the DigitalDisplay Working Group (DDWG). DVI is useful for coupling a video source,such as a camera, to a video monitor. The video signals input to thematrix switch may come from cameras or other devices that provide outputin the form of a video image. The video signal output from the matrixswitch may be used to drive video monitors and/or input to recorder,image capture, streaming and/or conferencing devices.

The components of the system, either alone or in concert with the systemas a whole, may permit a user to determine a source of a lack of videoimagery on an otherwise functioning video monitor. The components of thesystem may also allow a user to distinguish between the capabilities oftwo pieces of equipment that each performs the same general function.Components of the system may also facilitate the presentation of, orprevent the presentation of, text overlays (or equivalents thereof) ofpatient information on video monitors, thereby improving safety and toprotecting privacy.

According to one aspect, a component of the system may receive, from agiven piece of equipment associated with that component, a video signalof a first type and convert the video signal to a second predeterminedtype for application to a digital video matrix. According to one aspect,the component may store data for identifying the given piece ofequipment with greater granularity than previously existed. Thecomponent may store data indicative of whether the given piece ofequipment associated with that component provides equipment informationin a video stream presented to the component (e.g., a “modality providedby source” flag) and/or provides patient information in the video streampresented to the component (e.g., a “patient information provided bysource” flag). The component may additionally or alternatively storedata indicative of a status of a video signal input to the component,and may be configured to present predetermined video imagery on amonitor to indicate a failure to receive an expected video signal fromthe equipment to which it is associated. The component may be referredto as a converter device herein.

Operational Environment

FIG. 1 provides an example of an operational environment 100 in which asystem, including a converter device, may find utility. The operationalenvironment used to illustrate aspects of the system in general and theconverter device in particular is that of a hospital and hospitaloperating rooms. This operational environment is for illustrative anddescriptive purposes; it is not intended to be limiting.

An operating room may include, for example, a surgical robot 102, asurgical-light mounted camera 104, a microscope 106, a C-Arm 108(mounting, for example, an X-ray or fluoroscope machine), an endoscope110, an ultrasound machine 112, and an observation camera 114 mounted toa wall of the operating room.

As illustrated for exemplary purposes, the surgical-light mounted camera104 and the observation camera 114 are shown without integrated videomonitors. The surgical robot 102, microscope 106, endoscope cart 110,and ultrasound 112 are each depicted as having one integrated videomonitor 116A, 116B, 116E, 116F. The C-arm 108 is depicted as having twointegrated video monitors 116C, 116D. In addition, the operating room100 may include one or more auxiliary video monitors 118A, 118B, 118C,118D, and one or more recorders, image capture, streaming, and/orconferencing devices 118E that are coupled to a digital video matrix 120coupled to a server 122 of the overall system.

The server 122 may include a processor of the overall system (referredto herein as a system processor 124) coupled to the digital video matrix120 and a memory (referred to herein as a system memory 126) coupled tothe system processor 124. The digital video matrix 120 and/or server 122may be located inside or outside of the operating room.

In this description, there is a distinction drawn between the integratedvideo monitors 116A, 116B, 116C, 116D, 116E, 116F, which are understoodto be the video monitors integral to their respective pieces ofequipment 102, 106, 108, 110, 112—and the auxiliary video monitors 118A,118B, 118C, 118D (hereinafter referred to as video monitors 118A, 118B,118C, 118D or video monitors A-D) that are coupled to the digital videomatrix 120 and which receive input from the digital video matrix 120.Any reference to a video monitor made hereinafter should be construed asa reference to an auxiliary video monitor such as video monitors 118A,118B, 118C, 118D.

Each piece of equipment 102-114 may include a capability to provide, asan output, a video signal (referred to herein alternatively as a videofeed or a video signal 130A, 130B, 130C, 130D, 130E, 130F, 130G) togenerate an image on one or more video monitors 118A, 118B, 118C, 118D.

In the illustrative example of FIG. 1, the number of pieces of equipment102-114 is greater than the number of video monitors 118A, 118B, 118C,118D and/or recorders, image capture, streaming, and/or conferencingdevices 118E. The example is not limiting; the number of pieces ofequipment can be greater than, less than, or equal to the number ofvideo monitors.

The system to multiplex a video feed from each of the pieces ofequipment 102-114 to one or more video monitors (e.g., 118A-D) and/orrecorders, image capture, streaming, and/or conferencing devices (e.g.118E) may include a plurality of converter devices 132A, 132B, 132C,132D, 132E, 132F, 132G (individually and collectively referred to asconverter device(s) 132, converter devices 132A, 132B, 132C, 132D, 132E,132F, or 132G, or converter devices 132A-G). One or more converterdevices 132 may be associated with each piece of equipment 102-114. Byway of example, in FIG. 1, there is a one-to-one relationship between anumber of pieces of equipment 102, 104, 106, 108, 110, 112, 114 and thenumber of converter devices 132A, 132B, 132C, 132D, 132E, 132F, 132G,respectively.

According to one aspect, each converter device 132A-G may be configuredto accept, as input, one video feed of a first type, convert the firsttype to a second predetermined type, and provide, as output, one videofeed of the second type. The first and second types may be the same ordifferent. Nothing herein is meant to limit the number of inputs and/oroutputs of the converter devices 132A-G.

Each converter device 132 in the plurality of converter devices may becoupled to the digital video matrix 120. Coupling may be via aninterface device 134A, 134B, 134C, 134D, 134E, 134F, 134G (individuallyand collectively referred to as interface device(s) 134).

In some aspects, voltage to operate the converter device 132 may beprovided to the converter device 132 via the interface 134. In someaspects, voltage to operate the converter device 132 may be provided tothe converter device 132 from an AC-DC converter (not shown). In someaspects, voltage to operate the converter device 132 may be provided tothe converter device 132 from the piece of equipment to which theconverter device is coupled.

As depicted in FIG. 1, the digital video matrix 120 may be coupled tovideo monitors 118A, 118B, 118C, 118D, and recorders, image capture,streaming, and/or conferencing devices 118E in the operating room. Thislist is exemplary and non-limiting. In one aspect, the video monitorsmay include, for example, a touch panel video monitor, ananesthesiologist's video monitor, a surgeon's video monitor, and a wallmounted video monitor. A fewer or greater number of video monitors arewithin the scope of any aspect described herein.

The digital video matrix 120 may also be coupled to remote videomonitors, such as conference room video monitor 136, a nurses' stationvideo monitor 138, and/or video monitors of administrative staff, suchas, for example, a clinical engineering department video monitor 140.The clinical engineering department may have responsibility forinventory control and/or maintenance of the equipment to which theconverter devices are attached. The digital video matrix 120 may also becoupled to mobile devices such as an iPad, iPhone, Android, etc.Coupling to remote monitors and mobile devices may be achieved at a homeor office securely.

The coupling of the outputs of the plurality of converter devices 132 tothe digital video matrix 120 and the coupling of the outputs from thedigital video matrix 120 to remote video monitors 136, 138, 140, may bevia the hospital's internal network 142. Using known communication andsecurity protocols, any video monitor, including remote video monitors136, 138, 140 may be coupled to the digital video matrix 120 vianetworks external to the hospital, such as the Internet.

System with Multiple Servers

FIG. 2 is a block diagram illustrating an aspect in which three rooms250, 252, 254, each served by their own server 222A, 222B, 222C (similarto 122, FIG. 1), send video out over a network 242. The rooms may beoperating rooms. Each server 222A, 222B, 222C may also send video todisplay devices and/or recording devices in the room in which it islocated. Each server 222A, 222B, 222C may include its own digital videomatrix 220A, 220B, 220C (similar to 120, FIG. 1).

In one aspect, a user at a remote video monitor, such as at a nurses'station video monitor 240 or a clinical engineering department videomonitor 236, may be able to view a dynamically changing list of eachpiece of equipment 202, 204, 206, 208, 210, 212, 214 presently coupledto all servers 222A, 222B, 222C via converter devices 232A, 232B, 232C,232D, 232E, 232F, 232G (similar to 132, FIG. 1). The list may includeinformation at a level of granularity sufficient to distinguish betweenthe features of two pieces of equipment that perform the same function.

For example if the hospital has three microscopes designated for use inoperating rooms, there may be an assumption that each microscope is inits respective operating room and is being used throughout eachscheduled surgery. In reality, a microscope, such as microscope 204 inoperating room 254, might be used for a short period at the beginning,middle, or end of a surgical procedure. At other times, over the courseof a surgery scheduled to last several hours, the valuable piece ofequipment (i.e., the microscope 204) may be unused.

Use of the system, depicted in exemplary FIG. 2, permits a user at aremote video monitor (e.g., 236, 240) to visually observe each operatingroom 250, 252, 254 using a wall mounted camera 206, 210, 214 (eachsimilar to 114, FIG. 1). While the illustrative example of FIG. 2depicts a wall mounted camera in every room 250, 252, 254, no room isrequired to have a wall mounted camera. Their presence in FIG. 2 is fordescriptive purposes. In one aspect, in addition to or instead of a wallmounted camera, a list of converter devices inside each operating roommay be presented to a user in text and/or graphic form on a user'sdisplay. The list may show what is connected to the server and identifyeach piece of equipment using the parameters associated with the pieceof equipment as previously programmed into the converter device. If aroom camera is available it can be used to visually look into theoperating room to see if the actual device is in use. If a given pieceof equipment was used and unplugged, the list may show that it waspreviously connected to the router in the room but the text and/orgraphics associated with the piece of equipment may be grayed out.Device tracking may also be supported. In this case, if a converterdevice and/or the piece of equipment to which it is coupled are equippedwith an asset tracking device, then a system according to aspectsdescribed herein may obtain the asset tracking information through thehospital's network to locate the piece of equipment.

Returning to FIG. 2, observation, for example by wall mounted cameras206, 210, 214 may permit one to determine whether the microscope 204 isin one of the operating rooms and, if in the operating room, may permitthe user to determine if the microscope 204 is being used. The user maythen identify, from the sufficiently high granularity of the informationdescribing the microscope 204, whether the microscope 204 has a desiredfeature that other microscopes are lacking, for example, a certain typeof optical filter. If the user can confirm that the microscope 204 hasthe desired feature, the user can ask an operating room 254 nurse if themicroscope 204 can be removed from operating room 254. Removal may bedue to a need to use the microscope in another operating room 250 or252, for routine maintenance, or for warranty repair.

In one aspect, converter devices 232A-G, each coupled to a given pieceof equipment 202-214, can be used to store multiple items of informationabout that particular piece of equipment that may be more useful thanjust a descriptor of the equipment type. In addition to equipment type,the stored information may include, for example, manufacturer, modelnumber, serial number, total runtime (e.g., hours of operation),maintenance due date, asset tracker ID, and flags such as a flag toindicate whether the piece of equipment itself provides patientinformation in its video feed and/or a flag to indicate whether thepiece of equipment itself provides modality information (e.g.,manufacturer, model number, serial number, etc.) about itself in itsvideo feed. The stored information can also include an indication of thestatus of the video 230A-G being received by the converter device 232(e.g., video input present, or not present).

One or more of the exemplary types of information recited above may beentered into a memory device (e.g., 320, FIG. 3) of the converter device232 and stored for future use. The information may be entered, forexample, during setup of the converter device 232 when it is initiallycoupled to a given piece of equipment.

Converter Device

FIG. 3 is a block diagram of a converter device 300 according to oneaspect. The converter device 300 may include, a first connector 302, avideo front end circuit/module/function 304 (hereinafter video front end304), a digital video converter circuit/module/function 306 (hereinafterdigital video converter 306), an image generator circuit/module/function308 (hereinafter image generator 308), a communicationcircuit/module/function 310, a transmitter/receivercircuit/module/function 312 (hereinafter transmitter/receiver 312), asecond connector 314, a power supply 316, a processor 318, and a memory320. This list is illustrative and not limiting.

The first connector 302 may be configured to couple to a plurality ofinput/output connector types, thereby accommodating the plurality ofinput/output connectors that may be expected to be serviced by theconverter device 300. Input signal interface types may include any of aplurality input formats that may be expected to be serviced by theconverter device 300. In one aspect, the interfaces may be those definedby national or international standards. Interfaces may include, forexample, RGB analog, S-Video, or other types of analog inputs, any of aplurality of digital interfaces such as, for example, High-DefinitionMultimedia Interface (HDMI), Digital Visual Interface (DVI), SerialDigital Interface (SDI), and/or Universal Serial Bus (USB). Thepreceding list is illustrative and not limiting.

The video front end 304 may be a decoder, for example, configured todecode standard or high definition video signals. For example, videocomes in a variety of formats. Some analog video formats come with thecolor information, brightness information, and video sync signals“encoded” into a single video feed. Other non-analog video formats suchas DVI or serial digital interface (SDI), HD-SDI, 3G-SDI are digitalformats that are encoded with extra information so that the receivingdevice can easily lock on to these signals and decode them. The videofront end 304 could include an analog-to-digital converter for receptionof analog signals and/or an equalizer for digital formatted signals. Thevideo front end 304 may generally be configured to place any of apredetermined number of types of input signals into a digital videoformat.

The digital video converter 306 may convert the format of the digitaldata received from the video front end 304 to a second digital formatguaranteed to be useable by a system processor (e.g., 124, FIG. 1)associated with a digital video matrix (e.g., 120, FIG. 1). For example,in one aspect the second digital format may be an RGB 4:4:4 digitalformat. The conversion may be done on a pixel-by-pixel timeframe. Theformat of the signal received by the digital video converter 306 may notbe the same as the format of the digital signal output from the digitalvideo converter 306. The digital video converter 306 may be a “zerodelay” digital video converter. The term “zero delay” may infer thatthere is substantially little delay in the circuit. In one aspect,actual delay of a zero delay converter may be less than about 10microseconds. In some aspects, the digital video converter 306 may cleanup a synchronization signal. In some aspects, the output of the digitalvideo converter 306 may be four high-speed serial lines in parallel.

The image generator 308 may be used to generate, in one aspect, a videosignal representative of an informational image.

The communication circuit/module/function 310 may serve as abidirectional communication interface between the digital video matrix(e.g., 120, FIG. 1) and the converter device 300.

Generating Informational Display and Message

FIG. 4 illustrates an informational message, such as one that may begenerated by an image generator (see, for example, circuit 308 of FIG.3) of a converter device. As illustrated in FIG. 4, a system including aserver 410 having a digital video matrix 420 (similar to 120, FIG. 1), asystem processor 424 (similar to 124, FIG. 1), and a system memory 426(similar to 126, FIG. 1) may receive input data from a number ofconverter devices 432A, 432B, and 432C (similar to 132, FIG. 1). Theoutput of the server 410 may be routed to any or all of video monitors442, 444, 446.

A converter device 432A may receive data representative of an imagereceived from a gastroscope 402. The converter device 432A may convertthe data from a first format to a second format for output to the server410. The output data 412 of the converter device 432A may include datarepresentative of the image received at the input of the converterdevice 432A. The output data 412 of the converter device 432A may berouted by the server 410 to a video monitor 442 for display thereon.

Another converter device 432C may receive data representative of animage received from a C-Arm 406. The converter device 432C may convertthe data from a first format to a second format for output to the server410. The output data 416 of the converter device 432C may include datarepresentative of the image received at the input of the converterdevice 432C. The output data 416 of the converter device 432C may berouted by the server 410 to a video monitor 446 for display thereon.

Another converter device 432B may be coupled to a microscope, but novideo signal 404 is being received from the microscope at the input ofthe converter device 432B. The image from the microscope may have beenintended to be routed by the server 410 to a video monitor 444. The lackof a video signal 404 from the microscope may be due, for example, tothe power for the microscope being in an OFF state. To indicate that theproblem is not in the path from, for example, the output of theconverter device 432B to the monitor 444, the converter device 432B maygenerate, using an image generator (see, for example, not shown, circuit308 of FIG. 3) a predetermined image 414. The image 414 may be, forexample, a fixed image, such as a series of vertical stripes ofdifferent colors abutted against one another. Other images, includingmoving images, may be used.

In one aspect, the system processor 424 may cause informational text tooverlay (or equivalent thereof) the predetermined image 414. Theresultant compound image 114 Overlay may read, for example, “No Video.Check Input Equipment Power” and may include one or more items ofidentification of the piece of equipment to which the converter device432B was pre-programmed to be coupled to. For example, the text overlay(or equivalent thereof) may read “No Video from Olympus model no. 12345microscope, serial number 102030. Check microscope power.” Other textoverlays (or equivalents thereof) may be used. Notably, thepredetermined image 414 and compound image 114 Overlay automaticallyappears and may be displayed until the processor of the converter device432 validates the incoming video signal. Therefore, in one aspect, it isthe converter device 432 that automatically generates the predeterminedimage 414, determines if the input video signal or predetermined image414 is presented to the server 410 (via a determination of the validityof the input video signal) and provides the data for the compound image114 Overlay.

Converter Device (Continued)

Returning now to FIG. 3, the transmitter/receiver 312 may be, in oneaspect, an aggregator of data. For example, if the digital videoconverter 306 outputs a plurality of serial data streams, each datastream at a given speed, the transmitter/receiver 312 may take theplurality of signals and combine them into a single higher-speed videoformat output signal for transmission to the digital video matrix (e.g.,120, FIG. 1).

In another aspect, the transmitter/receiver 312 may receiveinstructions/queries from the system processor (e.g., 124, FIG. 1)associated with a digital video matrix (e.g., 120, FIG. 1) and forwardthe instructions/queries to the communication interface 310. Thecommunication interface 310 may, in turn, forward theinstructions/queries to the processor 318 of the converter device 300.The processor 318 may calculate, or otherwise obtain, a response to theinstructions/queries and return the response to the communicationinterface 310. The communication interface 310 may, in turn, return theresponse to the transmitter/receiver 312. The transmitter/receiver 312may, in turn, forward the response to the system processor (e.g., 124,FIG. 1) associated with a digital video matrix (e.g., 120, FIG. 1).

The second connector 314 may include contacts forming a physicalinterface that may be of a proprietary or non-proprietary configuration.In one aspect, the connector 314 may be configured to be coupled,directly or via an interface (such as interface 134, FIG. 1), to theserver (e.g., 122, FIG. 1 or 222, FIG. 2).

The power supply 316 may include, in one aspect, an internal voltageconverter (not shown) to convert a DC line voltage to one or morepredetermined DC voltages for operating the converter device 300. Inanother aspect, the power supply 316 may receive operating voltage(s)from an interface (such as interface 134, FIG. 1) and distribute thereceived operating voltage(s) to the components of the converter device300. In one aspect, the power supply 316 may filter the operatingvoltage received from the interface (such as interface 134, FIG. 1)prior to distributing the operating voltage(s) to the components of theconverter device 300.

The processor circuit 318 may read data, such as instructions andpredefined data string values, from the memory 320. In one aspect, theinstructions may cause the processor circuit 318 to configure the videofront end 304, for example, to receive an input of a predeterminedformat from the piece of equipment to which it is coupled. For instance,the video front end 304 may be coupled to a piece of equipment that isexpected to present an analog signal of a given format to the videofront end 304. The processor circuit 318 may therefore issue commands tocause the video front end 304 to be configured for an analog-to-digitalconversion. By way of another example, the video front end 304 may becoupled to a piece of equipment that is expected to present a digitalsignal in a standard definition format to the video front end 304. Theprocessor circuit 318 may therefore issue commands to cause the videofront end 304 to be configured to convert the digital signal in thestandard definition format to another format suitable for input to thedigital converter 306. In some aspects, the configuration of the videofront end 302 may be accomplished by having the processor circuit 318write predefined data to registers associated with the video front end304. These registers may be used to configure the video front end 304 toaccept one of a plurality of different types of input. In some aspects,the input and output of the video front end may have the same format.

In one aspect, the instructions may cause the processor 318 to configurethe digital video converter 306. In one aspect, the instructions maycause the processor 318 to configure the image generator 308. In oneaspect, the instructions may cause the processor 318 to configure thecommunication interface 310. In one aspect, the instructions may causethe processor 318 to configure the transmitter/receiver 312.Configurations may be accomplished, for example, by programmingregisters associated with the given circuit/module/function 306, 308,310, 312 or otherwise communicate with the given circuit/module/function306, 308, 310, 312.

In one aspect, the instructions may cause the processor 318 to writedata to, or read data from, the memory 320. For example, an externaldevice may send a query to the converter device 300 to retrieve certaininformation stored in the memory 320 of converter device 300. Theinformation may include equipment identification information and/orvalues of various flags, and/or status of a video input signal presentedto the converter device 300.

In one aspect, the instructions may cause the processor 318 to calculatea cumulative runtime of the piece of equipment and to write thecalculated runtime to the memory 320. Calculations may be performedcontinually or periodically. The cumulative runtime could be, forexample, the number of hours the piece of equipment has been in an ONstate. For example, the converter may have a real-time clock thatupdates the memory once a minute while the equipment is in the ON state.The run time may be written to two memory locations in a toggle format.For instance, a first write is written to location 1, a second write iswritten to location 2, a third write is written to location 1, so on andso forth. If power is abruptly removed during a memory write, the lastknown good memory write may be used once the converter device is poweredback on. By way of another example, the number of hours that the pieceof equipment has presented a video valid signal to an input of theconverter device 300 may be measured. This may be implemented, forexample, by the zero delay digital video convertercircuit/module/function 306, which may perform real time video timingmeasurements that are passed on to the processor circuit 318 forvalidation, e.g., to determine if the video is valid or invalid.

Keeping track of the runtime of a given piece of equipment may be usefulif the equipment fails, and the warranty is tied to the amount of timethe equipment is in use. Alternatively, the runtime can be calculated bythe system processor (e.g., 124, FIG. 1) associated with the system as awhole. The resulting data can be written to the memory 320 of theconverter device 300 from the system processor associated with thesystem as a whole.

As indicated above, the processor 318 of the converter device 300 maycommunicate with a system processor (e.g., 124, FIG. 1) that may haveoverall control of the system as a whole. The system processor may belocated with the video matrix in a server, or may be part of a computer,such as a Linux computer, associated with the system. A user interface(not shown) may be located at any video monitor, for example in theoperating room and/or remote to the operating room. The user interfacemay permit a user to enter data that can be saved as one or more stringswithin the memory 320 of the converter device. The processor 318 of theconverter device 300 may communicate with the system processor during,for example, an initial set-up of the converter device 300.

The memory 320 may be a non-volatile memory, such as a flash memory. Theprocessor 318 may communicate with the memory 320. The memory 320 may beused to store data, for example, in text strings that are unique to agiven piece of equipment coupled to the converter device 300. The memory320 may store, for example, the following strings of data that may bepresented to the memory 320 during set-up of the converter device 300.

-   -   String 1: generic name of piece of equipment (e.g., surgical        robot, surgical-light camera, microscope, C-arm, endoscope,        ultrasound, or room observation camera);    -   String 2: model number of piece of equipment;    -   String 3: serial number of piece of equipment;    -   String 4: hours of operation (e.g., cumulative run-time) of the        piece of equipment;    -   String 5: data indicative of whether the given piece of        equipment provides equipment information in the video stream        presented to the converter device 300 (e.g., a “modality        provided by source” flag);    -   String 6: data indicative of whether the given piece of        equipment provides patient information in the video stream        presented to the converter device 300 (e.g., a “patient        information provided by source” flag); and/or    -   String 7: Input video status.    -   String 8: Asset tracking ID may include an asset ID number for        real-time location system (RTLS) or other types of tracking        devices attached to equipment.    -   String 9: De-Identification x-y coordinates used to provide        location information of patient information embedded in the        video which could be used to mask this information while        conferencing or streaming video to remote locations in order to        protect the patient's confidentiality.

The preceding list of strings is illustrative and not intended to belimiting. Information, such as that associated with the exemplaryrecited seven strings, or any other information, can be stored in thememory 320 of the converter device.

In one aspect, as indicated above, the zero delay digital videoconverter circuit/module/function 306 may perform digital videoprocessing on an input signal and may provide detailed video timing datato the processor 318. The processor 318 may then determine if thedetailed timing data provided by zero delay digital video convertercircuit/module/function 306 is valid. In this way, according to thisaspect, the converter device may determine that the input signal is avalid video input signal. The converter device may automatically, byaction of the processor 318 and without any input from the server, useswitch 322 to switch the signal presented to the zero delay digitalvideo converter circuit/module/function 306 between the signal from thevideo front end circuit/module/function 304 and the signal from theimage generator circuit/module/function 308 based on the determination.

In one aspect, the system, may be recording all data flowing into(and/or out of) the digital video matrix (e.g., 120, FIG. 1). Recordingsmay be made, for example, using a recorder 118E, FIG. 1. The recordingmay include recording data associated with any or all of the strings ofdata described above. Such data may be recorded as metadata. The systemmay also include in the recording, for example as metadata, patientinformation including patient demographics obtained, for example, from ahospital database. The system may also include this information withimage capture of still frames, streaming, and conferencing.

Inclusion of data such as, but not limited to, the data described abovemay be important, for example, to a surgeon reviewing the image capturesor recordings of data obtained during a surgery. First, association ofrecords with patient identification information is important to patientsafety. For correct diagnosis or follow-up care, the surgeon must besure that the image capture or recording he or she is reviewing belongsto the correct patient. Second, by way of example, if a surgeon notes ananomaly, or an indication of anything of importance, the surgeon canassociate that anomaly or indication to, for example, the model numberand serial number of a given piece of equipment and/or any otherinformation saved in the strings stored in the converter device 300.This could be important, for example, to determine whether the patient'scondition caused the anomaly or whether the given piece of equipmentcaused the anomaly.

Inclusion of data such as, but not limited to, the data described abovemay also be important, for example, in determining if a given piece ofis still under warranty. Many pieces of medical equipment do not comewith the runtime indicator and do not record their runtime;nevertheless, warranties on the medical equipment may be based onruntime. Thus, the tracking and storage of cumulative runtime may bebeneficial, for example, in disputes involving warranty expiration.

In one aspect, a converter device 300 may be permanently associated witha given piece of equipment (e.g., 102-114, FIG. 1). That is, eachconverter device 300 may be dedicated to one piece of equipment.Therefore the data, including cumulative runtime, stored in the memory320 of the converter device 300 is unique to that piece of equipment.This feature may aid a hospital in determining whether a failed piece ofequipment is under warranty. Additionally, this feature may aid ahospital in monitoring the expiry dates of clinical equipmentwarranties.

One or more of the information types recited above, and/or otherinformation, may be entered into the memory 320 of the converter device300 and stored for future use. The information may be entered, forexample, during setup of the converter device 300, when the converterdevice 300 is initially coupled to the piece of equipment. The memory320 may also include instructions that when executed by the processor318 cause the processor 318 to perform the methods of one or moreaspects of the system or converter device 300 described herein.

Display of Equipment and Patient Information

FIG. 5 is an illustration of a video monitor 446 of FIG. 4 showingequipment information (e.g., modality) 502 and patient information 504in an image displayed by a video monitor (e.g., video monitor 446). Inone aspect, the equipment information 502 and/or patient information 504may not obscure any of the patient video.

FIGS. 6A and 6B illustrate de-identification, where areas holdinginformation may be masked. Masking as presented in FIG. 6B may protectpatient confidentiality. In one aspect, de-identification coordinatesmay be created by the server and video matrix through a user interfaceafter the converter device is coupled to a piece of equipment. Thede-identification coordinates may then be stored in the memory of theconverter device. The de-identification coordinates may definede-identification regions 602, 604 that are sized and positioned on thevideo image produced by a given piece of equipment such that thede-identification regions may be superimposed upon any or allinformation displayed on the video image, such as personal information.As shown in FIG. 6B, the de-identification regions 602, 604 may be usedto mask the information from being visible on the image.De-identification coordinates may be read from the converter device andused to determine which portion(s) of the video the video matrix shouldmask out. This feature may find utility in scenarios whether patientinformation must be maintained in confidentiality, such as when thevideo is sent out to a streaming or conferencing codec. This featureadvantageously stores the de-identification coordinates in one or morestrings inside the memory of the converter device. In this way theinformation only needs to be established one time, when the converter isattached to a piece of equipment.

Set-Up and Use of Converter Device

FIG. 7 is a block diagram illustrating a method 700 of set-up and use ofa converter device. During set-up, the converter device may be coupledto a given piece of equipment 702. The converter device may be coupledto a source of power and to a communication network. The converterdevice may be recognized by the server. The server may beinterchangeably referred to as the “server” and/or “video router/server”herein. According to some aspects, once recognized, a user can programor update any of the converter device's parameters from the server'suser interface or from any remote connection over a network. Accordingto some aspects, a user performing the set-up may input a set of datastrings into a user interface. The data strings may be stored in memory704. The set of strings may include, for example, String 1 and any orall of the remaining 8 strings (Strings 2-9) described above. During usethe converter device may be coupled to a server of the system 706. Forinstance, a converter device

The system may obtain an identity of a patient, and may, using thatidentity, obtain patient information (demographics) from a hospitaldatabase via Health Level Seven (HL7) messaging 708. HL7 messaging is astandard used for electronic medical records, which manufacturers haveagreed to use for communication between different systems. HL7 providesfor messaging over a hospital's network. Information obtainable from ahospital's database may include patient name, patient initials, patientrecord identifier, patient demographics (e.g., age, race, sex, religion,address, etc.), as well as scheduling information indicating when thepatient is scheduled for a given operating room and case type. Any orall of this information may be automatically pulled into the system fromthe hospital's network via HL7 messaging.

The system may query the converter device to determine if the piece ofequipment coupled to the converter device provides information about theequipment and/or information about the patient to the converter devicein the video feed from the piece of equipment 710.

If, at 712, the system, based on a response from the converter device,determines that a flag is set to indicate that the piece of equipmentdoes not provide equipment information in its video stream to theconverter device, then, at 714, the system includes, as metadatapreselected equipment information with the video stream received fromthe converter device. If at 712 the system determines that the flag isset to indicate that the piece of equipment does provide equipmentinformation in its video stream to the converter device, then the methodproceeds to 716. If at 716 the system, based on the response from theconverter device, determines that a flag is set to indicate that thepiece of equipment does not provide patient information in its videostream to the converter device, then at 718 the system includes, asmetadata, preselected patient information with the video stream receivedfrom the converter device. If at 716 the system determines that the flagis set to indicate that the piece of equipment does provide patientinformation in its video stream to the converter device, then the methodproceeds to 720. At 720 the system directs the video stream receivedfrom the piece of equipment to a preselected video monitor and/or arecording device with, or without, added equipment and/or patientmetadata as determined at steps 712 and 716.

Accordingly, according to one aspect, the system is one which, based ondata stored in the converter device, may take data from one or moresources and associate that data with a video image provided by a pieceof equipment, such as a clinical piece of equipment. The association maybe by addition of the data to the video stream as metadata and/or asapplication of the data, in text overlay form (or equivalent thereof),within an image field of an image produced from the video stream. Theapplication of the text to the image may be turned on or off, on any oneor more video monitors, on any recording or image capture, streaming orconferencing, based on requirements of patient confidentiality. Theapplication of the text to the image may be done in real time, or verynear real time based, at least in part, on the delay of the video signalthrough the video converter device.

FIG. 8 is a block diagram illustrating a method 800 of use of aconverter device. The method may be operational at the converter device.A value indicative of whether predetermined information will be includedin video data to be received from equipment coupled to the converterdevice may be transmitted from the converter device 802. A determinationof whether the converter device is receiving video data from theequipment coupled to the converter device may be made 804. If theconverter device is receiving video data, the received video data may beconverted from a first format to a second predefined format at theconverter device 806. The converted video data may be transmitted to adigital video matrix 808. As an optional step, a calculation of acumulative runtime, during which the converter device is receiving videodata, may be made and the result of the calculation of cumulativeruntime may be stored in a data string in a memory of the converterdevice 810. The calculations may be performed periodically. If theconverter device is not receiving video data, the converter device maygenerate data representative of a predetermined image 812. The converterdevice may then transmit the generated data to a digital video matrix814. As an optional step, the converter device may transmit data storedin a memory of the converter device, wherein the data providesidentifying information related to the equipment coupled to theconverter device 816. The transmitted data may be used to add detailedtext to (or over) the predetermined image.

According to one aspect, the converter device may provide apredetermined video pattern after being connected to a power supply orpower supply and communications network. The converter device'sparameters (e.g., the stored strings) may be read by the video matrix(e.g., 120, FIG. 1) and/or a processor (e.g., 124, FIG. 1) of a server(e.g., 122, FIG. 1) and then one or more of the converter device'sparameters may be overlaid by the video matrix on top of thepredetermined video pattern as an informative message for an end user.For example, an ultrasound machine's converter may be plugged into apower source and communication network. A predetermined video patternmay be generated and sent to the video matrix. The video matrix and/orserver may read the converter device's parameters and overlay a messageon top of the predetermined video pattern such as “Ultrasound—PleasePower On Your Mobile Equipment.” In one aspect, the signal applied tothe input of the zero delay digital video convertercircuit/module/function 306 may be from the output of a single poledouble throw switch. The input to the switch may come from either thevideo front end circuit/module/function 304 or the image generatorcircuit/module/function 308, depending on the position of the switch.The processor circuit 318 may control the position of the switch.

One or more of the components and functions illustrated in the drawingsmay be rearranged and/or combined into a single component or embodied inseveral components without departing from the invention. Additionalelements or components may also be added without departing from theinvention. While certain exemplary embodiments have been described andshown in the accompanying drawings, it is to be understood that suchembodiments are merely illustrative of and not restrictive of thepresent disclosure, and that the present disclosure should not belimited to the specific constructions and arrangements shown anddescribed, since various other modifications are possible. Therefore, itis to be understood that, within the scope of the appended claims,embodiments of the present disclosure may be practiced other than asspecifically described herein.

Specific implementations shown and described are only examples andshould not be construed as the only way to implement the presentdisclosure unless specified otherwise herein. It is readily apparent toone of ordinary skill in the art that the various examples in thepresent disclosure may be practiced by numerous other partitioningsolutions.

One or more of the components, acts, features, and/or functionsdescribed herein and illustrated in the drawings may be rearrangedand/or combined into a single component, act, feature, or function orembodied in several components, acts, features, or functions. Additionalelements, components, acts, and/or functions may also be added withoutdeparting from the invention. Algorithms described herein may also beefficiently implemented in software and/or embedded in hardware.

In the description, elements, module/circuit/functions, and functionsmay be shown in block diagram form in order not to obscure the presentdisclosure in unnecessary detail. Conversely, specific implementationsshown and described are exemplary only and should not be construed asthe only way to implement the present disclosure unless specifiedotherwise herein. Additionally, block definitions and partitioning oflogic between various blocks is exemplary of a specific implementation.It is readily apparent to one of ordinary skill in the art that thepresent disclosure may be practiced by numerous other partitioningsolutions. For the most part, details concerning timing considerationsand the like have been omitted where such details are not necessary toobtain a complete understanding of the present disclosure and are withinthe abilities of persons of ordinary skill in the relevant art.

Also, it is noted that the embodiments may be described as a processthat is depicted as a flowchart, a flow diagram, a structure diagram, ora block diagram. Although a flowchart may describe the operations as asequential process, many of the operations can be performed in parallelor concurrently. In addition, the order of the operations may bere-arranged. A process is terminated when its operations are completed.A process may correspond to a method, a function, a procedure, asubroutine, a subprogram, etc. When a process corresponds to a function,its termination corresponds to a return of the function to the callingfunction or the main function.

Those of ordinary skill in the art would understand that information andsignals may be represented using any of a variety of differenttechnologies and techniques. For example, data, instructions, commands,information, signals, bits, symbols, and chips that may be referencedthroughout this description may be represented by voltages, currents,electromagnetic waves, magnetic fields or particles, optical fields orparticles, or any combination thereof. Some drawings may illustratesignals as a single signal for clarity of presentation and description.It will be understood by a person of ordinary skill in the art that thesignal may represent a bus of signals, wherein the bus may have avariety of bit widths and the present disclosure may be implemented onany number of data signals, including a single data signal.

It should be understood that any reference to an element herein using adesignation such as “first,” “second,” and so forth does not limit thequantity or order of those elements, unless such limitation isexplicitly stated. Rather, these designations may be used herein as aconvenient method of distinguishing between two or more elements orinstances of an element. Thus, a reference to first and second elementsdoes not mean that only two elements may be employed there or that thefirst element must precede the second element in some manner. Inaddition, unless stated otherwise, a set of elements may comprise one ormore elements.

Moreover, a memory, memory device, and/or storage medium may representone or more devices for storing data, including read-only memory (ROM),random access memory (RAM), magnetic disk storage mediums, opticalstorage mediums, flash memory devices and/or other machine-readablemediums and, processor-readable mediums, and/or computer-readablemediums for storing information. The terms “machine-readable medium,”“computer-readable medium,” and/or “processor-readable medium” mayinclude, but are not limited to non-transitory mediums such as portableor fixed storage devices, optical storage devices, and various othermediums capable of storing, containing, or carrying instruction(s)and/or data. Thus, the various methods described herein may be fully orpartially implemented by instructions and/or data that may be stored ina “machine-readable medium,” “computer-readable medium,” and/or“processor-readable medium” and executed by one or more processors,machines and/or devices.

Furthermore, embodiments may be implemented by hardware, software,firmware, middleware, microcode, or any combination thereof. Whenimplemented in software, firmware, middleware, or microcode, the programcode or code segments to perform the necessary tasks may be stored in amachine-readable medium such as a storage medium or other storage(s). Aprocessor may perform the necessary tasks. A code segment may representa procedure, a function, a subprogram, a program, a routine, asubroutine, a module, a software package, a class, or any combination ofinstructions, data structures, or program statements. A code segment maybe coupled to another code segment or a hardware circuit by passingand/or receiving information, data, arguments, parameters, or memorycontents. Information, arguments, parameters, data, etc. may be passed,forwarded, or transmitted via any suitable means including memorysharing, message passing, token passing, network transmission, etc.

The various illustrative logical blocks, modules,module/circuit/functions, elements, and/or components described inconnection with the examples disclosed herein may be implemented orperformed with a general purpose processor, a digital signal processor(DSP), an application specific integrated circuit (ASIC), a fieldprogrammable gate array (FPGA) or other programmable logic component,discrete gate or transistor logic, discrete hardware components, or anycombination thereof designed to perform the functions described herein.A general-purpose processor may be a microprocessor, but in thealternative, the processor may be any conventional processor,controller, microcontroller, or state machine. A processor may also beimplemented as a combination of computing components, e.g., acombination of a DSP and a microprocessor, a number of microprocessors,one or more microprocessors in conjunction with a DSP core, or any othersuch configuration. A general-purpose processor, configured forexecuting embodiments described herein, is considered a special purposeprocessor for carrying out such embodiments. Similarly, ageneral-purpose computer is considered a special purpose computer whenconfigured for carrying out embodiments described herein.

The methods or algorithms described in connection with the examplesdisclosed herein may be embodied directly in hardware, in a softwaremodule executable by a processor, or in a combination of both, in theform of processing unit, programming instructions, or other directions,and may be contained in a single device or distributed across multipledevices. A software module may reside in RAM memory, flash memory, ROMmemory, EPROM memory, EEPROM memory, registers, hard disk, a removabledisk, a CD-ROM, or any other form of storage medium known in the art. Astorage medium may be coupled to the processor such that the processorcan read information from, and write information to, the storage medium.In the alternative, the storage medium may be integral to the processor.

Those of skill in the art would further appreciate that the variousillustrative logical blocks, modules, module/circuit/functions, andalgorithm steps described in connection with the embodiments disclosedherein may be implemented as electronic hardware, computer software, orcombinations of both. To clearly illustrate this interchangeability ofhardware and software, various illustrative components, blocks, modules,module/circuit/functions, and steps have been described above generallyin terms of their functionality. Whether such functionality isimplemented as hardware, software, or a combination thereof depends uponthe particular application and design selections imposed on the overallsystem.

The various features and aspects described herein can be implemented indifferent systems without departing from the invention. It should benoted that the foregoing aspects are merely examples and are not to beconstrued as limiting the invention. The description of the variousaspects is intended to be illustrative, and not to limit the scope ofthe claims. As such, the present teachings can be readily applied toother types of apparatuses and many alternatives, modifications, andvariations will be apparent to those skilled in the art.

What is claimed is:
 1. A system, comprising: a plurality of converterdevices each communicatively coupled to a video source equipment suchthat there is a one-to-one association between each converter device andeach video source equipment, each of the plurality of converter devicesincluding a non-volatile memory circuit adapted to store equipment data,the equipment data including at least one of an elapsed operating time,a maintenance due date, manufacturer information, model information,and/or a serial number of the video source equipment communicativelycoupled to the converter device, and a processing circuitcommunicatively coupled to the non-volatile memory circuit, theprocessing circuit adapted to transmit the equipment data to a matrixswitch, convert video data received from the video source equipmentcommunicatively coupled to the converter device from a first format to asecond format, and transmit the converted video data in the secondformat to the matrix switch when the converter device is receiving thevideo data from the video source equipment communicatively coupled tothe converter device; and a video processing server including the matrixswitch, the matrix switch communicatively coupled to an output terminalof each of the plurality of converter devices and furthercommunicatively coupled to one or more video destination devices, and asystem processor communicatively coupled to the matrix switch, thesystem processor adapted to instruct the matrix switch to route videoreceived from the plurality of converter devices to the one or morevideo destination devices.
 2. The system of claim 1, wherein thenon-volatile memory circuit of each of the plurality of converterdevices is further adapted to store at least one flag value indicativeof whether the video source equipment communicatively coupled to theconverter device provides video signals to the converter device havingat least one of an equipment identifier or patient informationsuperimposed on the video signals.
 3. The system of claim 2, wherein thenon-volatile memory circuit of each of the plurality of converterdevices is further adapted to store de-identification coordinatesindicating spatial regions of the video signals that include at leastone of superimposed equipment information or patient information.
 4. Thesystem of claim 3, wherein the matrix switch receives a first convertedvideo data from a first converter device of the plurality of converterdevices, and the system processor is further adapted to: receivede-identification coordinates stored at a non-volatile memory circuit ofthe first converter device of the plurality of converter devices;utilize the de-identification coordinates to mask spatial regions thatinclude superimposed equipment information and/or patient information inthe first converted video data received from the first converter device;and instruct the matrix switch to route the first video data with themasked spatial regions to the one or more video destination devices. 5.The system of claim 2, wherein the system processor is further adaptedto transmit a query to any one of the plurality of converter devicesrequesting transmission of the flag value stored at the converterdevice, and the processing circuit of the converter device receiving thequery is adapted to transmit the flag value to the system processor inresponse to receiving the query.
 6. The system of claim 5, wherein thesystem processor is further adapted to: receive a first video signalfrom a first converter device of the plurality of converter devices, thefirst video signal based on an original video signal provided by a firstvideo source equipment communicatively coupled to the first converterdevice; receive a first flag value from the first converter device;generate a second video signal that includes at least one of a firstequipment identifier or first patient information superimposed onto thefirst video signal received when the first flag value indicates that atleast one of the first equipment identifier or the first patientinformation is not superimposed on one or more video images of the videosignals provided from the video source equipment to the first converterdevice; and instruct the matrix switch to transmit the second videosignal to a video destination device of the one or more videodestination devices.
 7. The system of claim 1, wherein the plurality ofconverter devices are each removeably coupled to the video sourceequipment and the matrix switch.
 8. The system of claim 1, wherein eachof the plurality of converter devices further include an image generatorcircuit adapted to provide a pre-defined video pattern, and theprocessing circuit is further adapted to: transmit the pre-defined videopattern to the matrix switch when the converter device is not receivingthe video data from the video source equipment communicatively coupledto the converter device.
 9. The system of claim 1, wherein each of theplurality of converter devices further includes a housing that contains,at least partially, the processing circuit and the non-volatile memorycircuit, the housing separate and independent to the video sourceequipment and the video processing server.
 10. The system of claim 1,wherein the video source equipment is medical imaging equipment.
 11. Asystem, comprising: a plurality of converter devices eachcommunicatively coupled to a video source equipment such that there is aone-to-one association between each converter device and each videosource equipment, each of the plurality of converter devices including aconverter circuit adapted to convert video data received from the videosource equipment communicatively coupled to the converter device from afirst format to a second format, a non-volatile memory circuit adaptedto store equipment data, the equipment data including at least one of anelapsed operating time, a maintenance due date, manufacturerinformation, model information, and/or a serial number of the videosource equipment communicatively coupled to the converter device, animage generator circuit adapted to provide a pre-defined video pattern,and a processing circuit communicatively coupled to the non-volatilememory circuit, the converter circuit, and the image generator circuit,the processing circuit adapted to transmit the equipment data to amatrix switch, transmit the converted video data in the second format tothe matrix switch when the converter device is receiving the video datafrom the video source equipment communicatively coupled to the converterdevice, and transmit the pre-defined video pattern to the matrix switchwhen the converter device is not receiving the video data from the videosource equipment communicatively coupled to the converter device; and avideo processing server including the matrix switch, the matrix switchcommunicatively coupled to an output terminal of each of the pluralityof converter devices and further communicatively coupled to one or morevideo destination devices, and a system processor communicativelycoupled to the matrix switch, the system processor adapted to instructthe matrix switch to route video received from the plurality ofconverter devices to the one or more video destination devices.
 12. Thesystem of claim 11, wherein the non-volatile memory circuit of each ofthe plurality of converter devices is further adapted to store at leastone flag value indicative of whether the video source equipmentcommunicatively coupled to the converter device provides video signalsto the converter device having at least one of an equipment identifieror patient information superimposed on the video signals.
 13. The systemof claim 12, wherein the non-volatile memory circuit of each of theplurality of converter devices is further adapted to storede-identification coordinates indicating spatial regions of the videosignals that include at least one of superimposed equipment informationor patient information.
 14. The system of claim 13, wherein the matrixswitch receives a first converted video data from a first converterdevice of the plurality of converter devices, and the system processoris further adapted to: receive de-identification coordinates stored at anon-volatile memory circuit of the first converter device of theplurality of converter devices; utilize the de-identificationcoordinates to mask spatial regions that include superimposed equipmentinformation and/or patient information in the first converted video datareceived from the first converter device; and instruct the matrix switchto route the first video data with the masked spatial regions to the oneor more video destination devices.
 15. The system of claim 12, whereinthe system processor is further adapted to transmit a query to any oneof the plurality of converter devices requesting transmission of theflag value stored at the converter device, and the processing circuit ofthe converter device receiving the query is adapted to transmit the flagvalue to the system processor in response to receiving the query. 16.The system of claim 15, wherein the system processor is further adaptedto: receive a first video signal from a first converter device of theplurality of converter devices, the first video signal based on anoriginal video signal provided by a first video source equipmentcommunicatively coupled to the first converter device; receive a firstflag value from the first converter device; generate a second videosignal that includes at least one of a first equipment identifier orfirst patient information superimposed onto the first video signalreceived when the first flag value indicates that at least one of thefirst equipment identifier or the first patient information is notsuperimposed on one or more video images of the video signals providedfrom the video source equipment to the first converter device; andinstruct the matrix switch to transmit the second video signal to avideo destination device of the one or more video destination devices.17. The system of claim 11, wherein the plurality of converter devicesare each removeably coupled to the video source equipment and the matrixswitch.
 18. The system of claim 11, wherein each of the plurality ofconverter devices further includes a housing that contains, at leastpartially, the processing circuit, the non-volatile memory circuit, theconverter circuit, and the image generator circuit, the housing separateand independent to the video source equipment and the video processingserver.
 19. The system of claim 11, wherein the video source equipmentis medical imaging equipment.
 20. A method operational at a system thatincludes a plurality of converter devices each communicatively coupledto a video source equipment such that there is a one-to-one associationbetween each converter device and each video source equipment, each ofthe plurality of converter devices including a non-volatile memorycircuit adapted to store equipment data, the equipment data including atleast one of an elapsed operating time, a maintenance due date,manufacturer information, model information, and/or a serial number ofthe video source equipment communicatively coupled to the converterdevice, the system further including a video processing server thatincludes a matrix switch, the matrix switch communicatively coupled toan output terminal of each of the plurality of converter devices andfurther communicatively coupled to one or more video destinationdevices, the method comprising: transmitting the equipment data storedat a first converter device of the plurality of converter devices to thematrix switch; converting video data received at the first converterdevice from a first video source equipment communicatively coupled tothe first converter device from a first format to a second format;transmitting the converted video data in the second format from thefirst converter device to the matrix switch when the first converterdevice is receiving video data from the first video source equipmentcommunicatively coupled to the first converter device; and instructingthe matrix switch to route the converted video data received from thefirst converter device to the one or more video destination devices.